Apparatus for blow line addition of thermosettable binder in fiberboard manufacture including a cooling nozzle

ABSTRACT

A method and apparatus for producing a synthetic board from cellulosic and/or lignocellulosic materials wherein a thermosettable binder, preferably a polyisocyanate binder, is applied through a cooled nozzle to the hot and wet fibrous material in the blow line out of the refiner of a board forming process. Polyphenylpolyisocyanates, such as a mixture of diphenylmethane-4,4&#39;-diisocyanate and polymethylene polyphenyl polyisocyanates, are a particularly suitable binder.

This is a division of application Ser. No. 371,895, filed Apr. 26, 1983,now U.S. Pat. No. 4,402,896.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a method and apparatus for producing asynthetic board from cellulosic and/or lignocellulosic materialsutilizing a polyisocyanate binder system. The binder is applied to thehot and wet fibrous material in the blow line out of the refiner of theboard forming process.

2. Description of the Prior Art

Many board products are manufactured by the basic process ofconsolidating or joining together bodies of cellulosic and/orligno-cellulosic materials or furnish using pressure, heat and achemical binder. Typical binders used in making such products arethermosetting resins such as phenol-formaldehyde,resorcinol-formaldehyde, melamine-formaldehyde, urea-formaldehyde,urea-furfural and condensed furfuryl alcohol resins. Another bindersystem, which has been gaining favor in recent years, involves the useof organic polyisocyanates, either alone or in combination with otherbinder materials, such as urea-or melamine-formaldehyde resins,phenol-formaldehyde resins, etc.

An advantage of polyisocyanate binders is that they can be used withhigh moisture-content furnish, thus reducing the costs of drying, andeliminating the "blue haze" sometimes found when drying to low moisturecontent. Also, the bonds developed with these binders are very resistantto water and thus have good exterior exposure characteristics.

Since polyisocyanate binders are highly reactive, their blending withthe furnish is conventionally accomplished at low temperature andhumidity conditions to avoid premature curing of the binder. Specialblending equipment must be provided and maintained in good working orderfor this purpose. If the blending system is not properly constructed andoperated, the result could be the production of inconsistent orlow-quality board. It would be highly desirable if an improved method ofproducing a synthetic board from ligno-cellulosic and/or cellulosicmaterials and polyisocyanate binders could be found which yields a highquality board product without requiring any complicated or expensiveblending equipment.

OBJECTS OF THE INVENTION

It is therefore an object of the present invention to provide animproved method of producing a synthetic board from ligno-cellulosicand/or cellulosic materials by employing as binder a polyisocyanateresin which is applied directly to the hot and wet fiber material in theblow line out of the refiner of a fiberboard manufacturing plant.

It is another object of the present invention to provide an improvedfiberboard production method which utilizes a pressurized refiningsystem and an isocyanate binder, wherein the isocyanate is applied tothe fibers to the blowline out of the refiner and no special resinblending equipment is used subsequently in the board making process.

It is still another object of the present invention to provide animproved method and apparatus which utilize the blow line addition of anisocyanate binder in the production of medium and high densityfiberboard.

It is yet another object of the present invention to provide a watercooled device for the introduction of undiluted or diluted isocyanate orother thermosettable resin binder into the hot blow line out of therefiner of a hardboard manufacturing plant.

It is a further object of the present invention to provide a boardproduct from cellulosic material, especially a medium or high densityfiberboard product, which has a combination of excellent properties,including superior strength and moisture resistance, through a boardmanufacturing process wherein an isocyanate binder is applied directlyto the hot moist fibers in the blow line out of the refiner of apressurized refining system.

These and other objects and advantages of the present invention willbecome more apparent to those skilled in the art when the instantdisclosure is read in conjunction with the accompanying drawings.

SUMMARY OF THE INVENTION

The above objects have been achieved in the fiberboard manufacturingprocess of the present invention, wherein the raw material to be formedinto the finished board product is refined at an intermediate pointduring the process into hot and wet fibrous material. It hasunexpectedly been found that a highly reactive isocyanate resin bindercan be applied to the intermediately formed, moist fibers while they arestill extremely hot without causing curing out of the isocynate resinduring subsequent processing. The finished products have excellentphysical characteristics.

In a preferred embodiment of the process of the present invention, thecellulosic and/or ligno-cellulosic raw material are subjected to a hightemperature steam treatment. A wax is preferably included with the rawmaterial to be steam treated. This steam treated material is thenreduced in size substantially to fibers by any known means such as bydefibrators having closely opposed, oppositely rotating discs or acombination of a rotating and a stationary disc. The steam treatment andfiberization are suitably accomplished in a pressurized refiner wherethe raw material is first fed into a steam digester, and, after thisinitial steaming is completed, is then passed to a refiner to fiberizethe material under further steam pressure. The hot and moist fibersformed in the refiner are blown by the steam passing therethrough into aline (so-called "blow line") leading from the refiner. The isocyanatebinder is injected through an entry port to the blow line onto the hotand moist fibers passing along inside the line. Air turbulence withinthe blow line brings about binder dispersion onto the fibers.

The resin treated fibers are blown into a dryer, such as a direct fired,tube type dryer, which reduces moisture to about 5 to 16%. The driedfibers are then formed into mats by a known vacuum/screen formingprocess. Finally, the mats are converted into the finished boardproducts in a conventional manner.

The polyisocyanate of the binder system may suitably be any organicpolyisocyanate compound containing at least 2 active isocyanate groupsper molecule, or mixtures of such compounds. Polyphenylpolyisocyanates,such as diphenylmethane-4,4'-diisocyanate and polymethylene polyphenylpolyisocyanates, are particularly suitable. A highly effective blow lineapplication of the polyisocyanate is achieved by emulsifying thepolyisocyanate prior to its application.

In carrying out the process of the present invention, a cooled nozzlemeans is located on the blow line for applying the isocyanate binder tothe hot and moist fibers being propelled within the blow line. Thecooled nozzle facilitates the introduction of diluted or undilutedisocyanate (or other thermosettable resin) into the hot blow line bypreventing or reducing advanced resin cure which would plug the nozzleif unchecked. The cooled nozzle advantageously comprises a resin infeedpipe which is attached to the blow line wall and communicates with theinterior of the blow line, and is surrounded by a heat exchange jacketthrough which cooling fluid is circulated. The jacket preferablycontains baffle means to increase turbulence and hence increase heattransfer.

DESCRIPTION OF THE DRAWINGS

The invention will now be described with reference to the accompanyingdrawings in which:

FIG. 1 is a diagrammatic representation of a flow sheet of the preferredembodiment of the method of the present invention for introducing apolyisocyanate binder in a synthetic board-making process;

FIG. 2 is a side cross-sectional view of a water cooled device forinjecting neat isocyanate binder into the blow line of a pressurizeddigester-refiner system;

FIG. 3 is a view, partially broken away, of the water cooled devicetaken along line 3--3 of FIG. 2, showing pipes 24 and 25 angled to aidwater circulation; and

FIG. 4 is a cross-sectional view taken on the plane of line 4--4 in FIG.2 and viewed in the direction indicated, showing one of the baffles ofthe water cooled device.

DETAILED DESCRIPTION OF THE INVENTION

The method of the present invention is suitable for processingcellulosic starting materials in general, and is particularly useful forforming wood chips into hardboard products. Mixtures of cellulosicparticles may be used. The production of a synthetic board in accordancewith the present invention typically starts with the screening of woodchips to remove therefrom both oversized and undersized material, as,e.g., fines and dirt. The chips also can be subjected to a preliminarywashing step.

After these preliminary operations, the cleaned chips are conveyed tostorage bins that feed pressurized digester-refiner systems, which canbe of a conventional design. The pressurized refiners refine the rawwoody material into fiber under steam pressure. The wood chips pass fromthe steam-pressurized digester into the refining section while stillunder pressure, and this pressure is maintained during the refining.

Referring to FIG. 1, a digester 10 is provided for presteaming of theraw chips. In practice, a number of digesters are used in combinationwith a like number of refiners in the board making process. Eitherhorizontal or vertical steam digesters of the continuous or batch typescan be used. Advantageously, molten wax is metered onto the chips asthey are fed to digester 10 in order to impart a degree of waterrepellancy to the board product. The wax suitably comprises about 0.5 to5% by weight, dry solids basis, of the formulation employed in makingthe board. Generally, steaming in the digester is carried out for aboutfive to ten minutes at a pressure of approximately 80 to 120 psi. In atypical operation, the chips are cooked in a horizontally or verticallyoriented, continuous steam digester for a period of about 5 minutes at100 psi steam pressure.

As the cooked chips emerge from the digester, they are blown through arefiner 11, which is also operated under steam pressure. Although bothsingle- and double-revolving disc refiners may be used, adouble-revolving-disc refiner has been found to be especially effectivein accomplishing the refining. The two counter revolving discs of thisrefiner are only a very small distance apart, as, e.g., about 0.05 inch.The discs are patterned with ridges and channels, and, as the chips passbetween these discs, they are shredded apart into individual fibers orfiber bundles, which are then blown through an orifice out of therefiner. The steam pressure in the refiner is usually 80 to 150 psig,corresponding to a temperature range of 320° to 365° F. The fibers whichemerge from the refiner into the blow line are at a moisture content of50% or higher by weight, as, e.g., 50-60%, based on the total solidsweight, and a temperature of at least about 212°-260° F., generallyabove about 245° F. After refining, the stock and steam are conveyedthrough blow line 12 to refiner cyclone 13, where the steam and fiberare separated.

It is known that the addition of phenolic resin binders through the blowline running from a pressurized refiner usually results in good resindistribution. However, the processing conditions encountered in thissystem are so severe that this method of addition has been avoidedheretofore in the case of isocyanate resins because of the very rapidcure tendencies of isocyanates at relatively low temperatures and withwater.

It has now, surprisingly, been found that isocyanate resin binders canbe added to the wet or semi-wet hot fiber in the blow line out of afiber refiner without any curing out of the isocyanate resin in theprocess. The isocyanate binder can be applied successfully to the fiberthrough the refiner blow line without resin buildup problems so as toproduce fiberboard having excellent physical properties. The isocyanatebinder is advantageously emulsified prior to its application into therefiner blow line. Because the isocyanate can be simply added to theblow line of an existing fiberboard manufacturing plant, there is noneed for special blending equipment and the maintenance of suchequipment.

The isocyanate resin is added to the blow line through cooled nozzle 20and mixes with the hot fiber emerging from the refiner. The isocyanatetreated fiber is then blown through cyclone 13 and is carried by beltconveyors 14 to a direct fired, dryer tube 15 (approximately 215 ft. inlength), which reduces moisture to about 5 to 16, preferably 10 to 16%.The treated fiber is on the belt conveyors for approximately 30 seconds,during which time it is at a temperature of at least about 200° F. Thedryer inlet and outlet temperatures are about 350° and 165° F.,respectively. The fiber remains in the dryer for about 2 or 3 seconds,and thereafter is conveyed through pollution control cyclones 16 and 17,with blower fan 18 providing an air stream to convey the fibers fromcyclone 16 to and through cyclone 17. The fibers entrained in the airstream are discharged from cyclone 17 and deposited on felters 19 to beformed into mats. The moisture content of the mat formed is generally 8to 16% by weight, on a dry weight basis.

Both the mat and subsequent board formations are accomplished in aconventional manner. Thus, the isocyanate treated fiber is convenientlyfelted onto a continuously moving screen which passes over a number ofvacuum boxes. Over each of the boxes a felting head deposits a uniformlayer of fiber onto the screen and these layers accumulate to thedesired weight. This continuous mat is then passed through apre-compressor which consists of a massive belt driven roll press thatcompresses the loose fiber mat and makes it more handleable insubsequent processing. After the pre-compressor, the mat is cut with aflying saw into the desired lengths and these are fed into aconventional board-forming press, such as a typical medium densityfiberboard press having multiple steam heated platens and optionallyequipped with an RF heating unit with from 600 to 1600 KW capacity. Thepress consolidates and compresses the mat to the desired thickness whileheat and optionally an RF heating unit cures the resin. During thepressing operation the mats are generally heated to a temperature ofabout 250°-400° F. as they are being compressed at about 100-600 psi.Pressing times are typically about 2-10 minutes. The exact conditions tobe utilized in the pressing and heat curing of the board product can, ofcourse, be easily selected by one skilled in the art depending upon thedesired characteristics of the finished product. It is beneficial toapply a release agent, such as, for example, silicone, glycerin or waxemulsion, on the press plates to minimize sticking. After pressing, theboards are trimmed to rough size and palletized, and may be allowed toage for several days. This aging allows the boards to equilibrate andtakes advantage of any postcuring that might occur in the stacks ofstored boards. The boards may then be sanded to close thicknesstolerances with sanders that use several grades of paper (usually60-80-100) and sand both top and bottom of the boards in a single pass.

The binder system to be introduced into the blow line in accordance withthe invention may suitably contain any organic polyisocyanate containingtwo or more isocyanate groups. The polyisocyanates which may be employedinclude the aliphatic, cycloaliphatic and aromatic polyisocyanates, andcombinations thereof. Representative of these types are the following:m- and p-phenylene diisocyanates, toluene-2,4- and 2,6-diisocyanates,diphenylmethane-4,4-diisocyanate, 4-chloro-1,3-phenylene diisocyanate,napthalene-1,5-diisocyanate, diphenylene-4,4-diisocyanate, 3,3'-dimethyldiphenylmethane-4,4'-diisocyanate,3-methyl-diphenylmethane-4,4'-diisocyanate, diphenylether diisocyanate,cyclohexane-2,4- and 2,3-diisocyanates, 1-methyl cyclohexyl2,4-and2,6-diisocyanates, bis(isocyanatocyclohexyl-) methane,2,4,6-triisocyanatotoluene, 2,4,4-triisocyanatodiphenyl ether,polymethylene polyphenyl polyisocyanates, methylene diphenyldiisocyanate, triphenylmethane triisocyanate,3,3'-ditolylene-4,4-diisocyanate, 4,4'-methylenebis(2-methyl-phenylisocyanate), hexamethylene diisocyanate, and cyclohexylene-1,3-and1,2-diisocyanates.

Preferred polyisocyanates among the foregoing are toluene-2,4- and2,6-diisocyanates, diphenylmethane-4,4-diisocyanate, polymethylenepolyphenylisocyanates, triphenylmethane triisocyanate, and mixturesthereof. Especially useful are water-emulsifiable and self-releasingisocyanate binders, such as those available from the Upjohn Company,Polymer Chemicals Division under the trademark "Isobind 100," and fromRubicon Chemicals Inc. under the trade designation Rubinate 4397-44.

The isocyanate binder system should have a viscosity which makes it safeand easy to handle in the process of the invention. Therefore, it isdesirable to use polyisocyanates whose molecular weight is from about200 to 10,000, preferably from 300 to 2,000. Polyisocyanates of too lowmolecular weight are quite volatile and toxic and accordingly moredangerous to use in a hot press. Polyisocyanates of too high molecularweight tend to be too viscous to be handled and used readily as binders.Even when polyisocyanates of too high molecular weight are emulsified toreduce their viscosity, they tend to be unstable and have a too limitedservice life.

Polyisocyanates of suitably high molecular weight may be prepared inknown manner by taking advantage of the reactive isocyanate groups andbuilding up the isocyanate to higher molecular weight. Chain buildersuseful for this purpose are those containing active hydrogen atoms, inparticular the polyesters and polyols, such as the glycols and glycolethers used in predetermined amount sufficient to produce reactivepolyisocyanate prepolymers of the desired molecular weight andisocyanate functionality.

Illustrative glycols and glycol ethers are the following: polyethyleneglycols to 6000 mol. wt. (200 to 2000 preferred), polypropylene glycolsto 6000 mol. wt. (200 to 2000 preferred), ethylene glycol monobutylether (butyl cellosolve), diethylene glycol monobutyl ether (butylcarbitol), ethylene glycol monoethyl ether (cellosolve), diethyleneglycol monoethyl ether (carbitol), cellosolve acetate, dimethoxytetraglycol, dipropylene glycol methyl ether, ethylene glycol monomethylether (methyl cellosolve), sorbitol, phenyl cellosolve, propylene glycolmethyl ether, triethylene glycol, tripropylene glycol methyl ether,glycols or polyglycols partially esterified with polycarboxylic organicacids such as adipic, sebacic, succinic, oxalic, etc., 2,4,6-hexanetriol, glycerol, propylene glycol partially esterified with adipic acid,trimethylol propane, and acrylic and methacrylic acid esters.

Where the polyisocyanate binder is capable of forming a stable emulsionin water, the binder may be emulsified and applied as an emulsion ofsuitably low viscosity, e.g., a viscosity of about 10 to 50 centipoisesmeasured at 25° C. In instances where the isocyanate binder is notemulsified prior to application, it may be applied typically at aviscosity of about 50 to 1000 centipoises at 25° C.

The quantity of binder needed in a particular application can bedetermined by simple experimentation. An application of from about 1 to10%, preferably 3 to 6%, of isocyanate binder, solids basis, isgenerally employed.

The present invention provides a simple and economical method ofapplying an isocyanate binder in the production of board products,especially medium and high density fiberboard products. Because theisocyanate simply is applied to and blends with the hot and moist fibersas these fibers are being propelled through the blow line out of therefiner, there is no need for special blending equipment and proceduresto accomplish the binder incorporation. Also, precise control ofmoisture content before hot pressing can be achieved in a single dryingstep, without the necessity for additional moisture control in ablending step. Another advantageous feature of the present invention isthat, by providing a particularly efficient technique for utilizing anisocyanate binder in the manufacture of hardboard, it makes it possibleto avoid the use of phenolic binders and the attendant disadvantagesassociated with the phenolics. For example, boards made with phenolicbinders generally require higher press temperatures and longer curetimes than isocyanate bound boards, thus necessitating greater energyexpenditures in producing the phenolic bound boards and rehumidificationto restore to these boards the moisture lost in the severe pressingstep. The present process is more energy efficient and eliminates thenecessity for board rehumidification which otherwise would normally berequired to achieve satisfactory out-of-press board moisture levels, as,e.g., 5 to 8% moisture.

FIG. 2 illustrates cooled nozzle 20, which can be used for injectingisocyanate binder into the blow line out of a pressurizeddigester-refiner apparatus. Cooled nozzle 20 enables undilutedisocyanate (or other resin binder) to be introduced into the hot blowline in the manufacture of hardboard. Cooled nozzle 20 comprises anelongated hollow central tube 21 having two open ends and an outer tubeor housing 22 arranged coaxially of the central tube and definingtherewith a cooling fluid duct 23 having one or more cooling fluidinlets 24 and one or more cooling fluid outlets 25 (only one inlet andoutlet shown in FIG. 2). The preferred cooling fluid is water.

Central tube 21, which advantageously extends horizontally outward fromblow line wall 26, can be formed of any suitable material, such as, forexample, copper, brass or steel piping. One open end 27 of tube 21 isadapted to communicate with blow line 12, while the other end 28 isadapted to communicate with a resin feed line 29, whereby resin fed fromsaid feed line into tube 21 in the direction of the arrow shown in FIG.2 is caused to pass through said tube and into the interior of said blowline. Inner tube end 27 is suitably attached, such as by welding, toblow line wall 26. Resin feed line 29 is fitted around outer tube end28.

Annular cooling fluid duct 23 is formed within tubular casing or housing22, which is composed of any suitable metal and arranged coaxiallyaround the central duct 21. Outer jacket casing 22 is suitably of muchlarger diameter than inner, resin feed pipe 21. The inner end of casing22 located to the exterior of inner tube end 27 is attached, such as bywelding, to blow line wall 26. Additionally, a circular plate-likemember 30 having a centrally located, circular opening for tube 21 iswelded or otherwise secured at both its outer and inner circular edgesto tubes 22 and 21, respectively, thus providing a totally enclosed,jacketed area about the inner tube 21. Outer end 28 of tube 21terminates a short distance to the exterior of this jacketed area toprovide a place for attachment of feed line 29 to the tube.

A short, cooling fluid feed pipe 24 of any suitable metal is secured(e.g., by welds) over a top opening in casing 22 so that pipe 24communicates with cooling fluid duct 23. A cooling fluid feed line 31 isfitted around the upper, free end of pipe 24. Advantageously, feed pipe24 is angularly positioned on casing 22 at a place near to blow linewall 26 to enhance fluid circulation and to direct the flow (illustratedby arrows in FIG. 2) of cooling fluid from feed pipe 24 toward thehottest area contacted by the injected isocyanate resin, i.e., theregion where isocyanate delivery tube 21 connects with blow line wall26. There is a critical need for cooling in this region to preventadvanced resin cure which would plug feed pipe 21. As shown in FIG. 3,pipe 24 is suitably angled from the vertical plane A-A to promoteswirling of the cooling fluid about tube 21 along the course indicatedby the arrows, and thereby enhance cooling.

The interior of cooling duct 23 advantageously is provided with at leastone baffle means 32 to increase fluid turbulence and hence increase heattransfer. As shown in FIGS. 2 and 4, baffle means 32 can comprise twovertically extending plates 33 and 34 located one above the other andspaced from each other. The plates may be manufactured from any suitablemetal. The outer (from the central tube wall) circular edges of upperand lower baffle plates 33, 34 are both welded or otherwise secured tothe inside of the outer tube's wall. Upper plate 33 completely encirclesinner tube 21, with the plate's inner circular edge welded or otherwisesecured to the outside of the inner tube's wall. The lower and upperstraight edges of plates 33 and 34, respectively, are spaced apart,whereby the plates in combination form a barrier across cooling fluidduct 23 except for the opening 35 between the plates. The baffle plates(4 combinations of plates are shown in FIG. 2) suitably are arrangedwithin cooling duct 23 so that the openings therethrough are alternatelylocated below and above central tube 21, i.e., in the combination ofplates to the right of plates 33, 34 in FIG. 2, it is the lower platewhich completely encircles inner tube 21, and so forth for the remainingtwo plate combinations. Other baffle means can be employed in coolingduct 23, such as a helical member(s) like the one described in U.S. Pat.No. 3,310,238. Additionally, the resin feed pipe surface which contactsthe cooling fluid can be threaded, knurled or similarly fashioned, as at36 in FIG. 2, to increase the surface area and improve heat transfer.

The direction of the cooling fluid's flow through the baffle arrangementof device 20 is shown by arrows in FIG. 2. The fluid (preferably coldwater), upon encountering the baffle members, has induced in it a motionwhich ensures effective circulation around feed pipe 21. After flowingthrough duct 23, the cooling fluid flows therefrom in the direction ofthe arrows into exit pipe 25, which is secured (e.g., by welds) to thelower, outer end of casing 22 and fitted with a fluid discharge hose 37.Outlet 25 comprises a short pipe of any suitable metal whose upper openend communicates with duct 23 through an opening provided in casing 22.Advantageously, exit pipe 25 is angularly positioned on casing 22 toenhance cooling fluid circulation. The fluid flowing into hose 37 can beconveyed to a drain or employed for any useful purpose, for example, assealing water, etc.

By permitting the neat addition of isocyanate or other resin binderdirectly into a hot blow line, the cooled nozzle of the inventioneliminates the need for any dilution-emulsification equipment andadditives. The device greatly simplifies the resin handling process andthus reduces both the equipment and finished board product costs.Alternatively, the device simply can be employed to cool partiallydiluted and emulsified isocyanate binders during their introduction intothe blow line to ensure against resin buildup at the blow line entrance.

The invention is further illustrated by the following example:

EXAMPLE

This example illustrates the application of isocyanate binder to hot andmoist wood fibers in the blow line out of a pressurized refiner in themanufacture of 3/8" hardboard siding.

The isocyanate binder used was Isobind 100, which is available from theUpjohn Company, Polymer Chemicals Division. An emulsion was prepared bydiluting this binder in a high shear mixer to 15% solids using waterwhich contained 1.5% Scripset 700, a surfactant available from MonsantoCompany.

The process of applying the emulsified isocyanate to the wood fibers canbe illustrated by reference to FIG. 1 of the drawings. Suitably screenedwood chips (mixed hardwoods, predominantly oak) were fed to digester 10.1.7% by weight of paraffinic wax, dry solids basis, was metered onto thechips as they were fed to the digester. Steaming in the digester wascarried out for about 5 minutes at a pressure of approximatly 100 psi.After exiting from digester 10, the cooked chips were blown throughrefiner 11, where they were subjected to 100 psi steam pressure, andinto blow line 12. The moist fibers which entered the blow line were ata temperature of about 250° F.

Application of the above-described isocyanate emulsion onto the woodfibers was accomplished by introducing the emulsion directly from thehigh shear mixer into refiner blow line 12. The isocyanate binder wasapplied at a level of 4% by weight, dry solids basis.

The treated wood fibers were blown through cyclone 13 for fiber andsteam separation, and through dryer 15 for moisture removal. Then, afterbeing blown through pollution control cyclones 16 and 17, the fiberswere deposited on felters 19 for mat formation. The mat moisture levelwas approximately 14%. The formed mat was subjected to apre-compression, and thereafter cut into desired lengths and fed to theboard-forming press. The press was maintained at a temperature of about350° F., and the press cycle time (cure time in press) started at 41/2minutes and then was reduced to 4, 31/2, 3 and 21/2 minutes. The mat wascompressed at about 500 psi pressure. The press closing speed was about45 seconds, and the press degassing rate was about 15 seconds. The caulplates, which were used to bound each side of the mat while it was beingpressed, were coated with Frekote 44, a release agent supplied byFrekote, Inc., Boca Raton, Fla., to prevent the fiberboard from stickingto these plates.

The properties of the resulting board products are set forth in thefollowing Table wherein the testing was according to ASTM D-1037-78A,and wherein:

MOR=modulus of rupture

IB=internal bond

MC=moisture content.

                                      TABLE                                       __________________________________________________________________________    PHYSICAL PROPERTY RESULTS                                                     Press                         24 HOUR      LINEAR                             Parameters                    WATER ABS.                                                                            BOARD                                                                              EXP. 6 CYCLE                                Cycle                                                                             DRY PHYSICAL TESTS                                                                             %   %   MOIST                                                                              %    %    %                        Press                                                                              Binder                                                                            Time                                                                              MOR DEN.                                                                              IB   DEN.                                                                              Thick.                                                                            Wt. MC   Thick.                                                                             Thick.                                                                             Retained                 Load %   min.                                                                              PSI PCF PSI  PCF Inc.                                                                              Inc.                                                                              %    Inc. Inc. MOR                      __________________________________________________________________________    1    4   41/2                                                                              6554                                                                              53.3                                                                              243  53.8                                                                              4.9 10.1                                                                              2.4  .10  8.9  83                       2    4   4   6047                                                                              52.3                                                                              184  52.8                                                                              6.0 11.8                                                                              4.0  .10  8.2  80                       3    4   31/2                                                                              6304                                                                              53.2                                                                              245  55.1                                                                              6.3 12.7                                                                              4.2  .10  7.5  81                       4    4   3   6191                                                                              53.1                                                                              218  54.2                                                                              6.1 11.4                                                                              5.3  .10  8.1  79                       5    4   21/2                                                                              5964                                                                              54.3                                                                              140  --  6.5 14.7                                                                              7.1  .17  9.5  68                       Typical                                                                            3.3 51/2                                                                              5500                                                                              52.0                                                                              175  --  5.0 12.0                                                                              0    .15  8.0  75                       Phenolic                                                                      __________________________________________________________________________

It can be seen from the results reported in the Table that an isocyanatebinder can be introduced directly into the blow line out of apressurized refiner so as to produce hardboard having very good wet anddry physical properties regardless of the cure time involved. Theperformance of each press load met commercial hardboard standards, andcompared favorably with the performance of hardboard made with aphenol-formaldehyde binder.

The above-described process can be facilitated by utilizing the coolednozzle of the invention at the injection port into the blow line. Use ofthe nozzle helps to avoid or minimize advanced resin cure at theinjection port during the continuous board forming process of theinvention.

Whereas the present invention has been described with respect tospecific embodiments thereof, it should be understood that the inventionis not limited thereto as many modifications thereof may be made. It is,therefore, contemplated to cover by the present application any and allsuch modifications as fall within the true spirit and scope of theappended claims.

We claim:
 1. In an apparatus for refining cellulosic material includinga pressurized refiner wherein said cellulosic material is subjected tothe action of steam under pressure and refined to hot and wet fibers,and a blow line communicating with said refiner for discharge therefromof said fibers, the improvement comprising an inner tube having resininlet and outlet ends, said resin inlet end being connected to a resinfeed line and said resin outlet end being connected to said blow line,and a housing disposed about said inner tube to define an enclosedjacketed area about said inner tube, said housing having at least onecooling fluid inlet means adjacent the one end of said housing locatedto the exterior of said resin outlet end of said inner tube, said atleast one cooling fluid inlet means being connected to a cooling fluidfeed line, and at least one cooling fluid outlet means adjacent theother end of said housing located to the exterior of said resin inletend of said inner tube, said at least one cooling fluid outlet meansbeing connected to a cooling fluid discharge line.
 2. The apparatus ofclaim 1 wherein said resin outlet end of said inner tube and said oneend of said housing located to the exterior of said resin outlet end areattached to the wall of said blow line, and said resin inlet end of saidinner tube extends a short distance outwardly of said other end of saidhousing.
 3. The apparatus of claim 2 wherein(a) said at least onecooling fluid inlet means comprises a feed pipe secured to said housingand communicating with said enclosed jacketed area, said feed pipe beingangularly positioned on said housing to direct the flow of cooling fluidfrom said feed pipe toward the region where said inner tube is attachedto said blow line wall and to promote swirling of said cooling fluidabout said inner tube, and (b) said at least one cooling fluid outletmeans comprises an exit pipe secured to said housing and communicatingwith said enclosed jacketed area, said exit pipe being angularlypositioned on said housing to enhance cooling fluid circulation.
 4. Theapparatus of claim 1 wherein said enclosed jacketed area is providedwith at least one baffle means to increase fluid turbulence.
 5. Theapparatus of claim 1 wherein the surface of said inner tube facing saidenclosed jacketed area is threaded or knurled to increase the surfacearea and thereby improve heat transfer.
 6. The apparatus of claim 1wherein(a) said resin outlet end of said inner tube and said one end ofsaid housing located to the exterior of said resin outlet end areattached to the wall of said blow line, and said resin inlet end of saidinner tube extends a short distance outwardly of said other end of saidhousing, (b) said at least one cooling fluid inlet means comprises afeed pipe secured to said housing and communicating with said enclosedjacketed area, said feed pipe being angularly positioned on said housingto direct the flow of cooling fluid from said feed pipe toward theregion where said inner tube is attached to said blow line wall and topromote swirling of said cooling fluid about said inner tube, and saidat least one cooling fluid outlet means comprises an exit pipe securedto said housing and communicating with said enclosed jacketed area, saidexit pipe being angularly positioned on said housing to enhance coolingfluid circulation, (c) said enclosed jacketed area is provided with atleast one baffle means to increase fluid turbulence, and (d) the surfaceof said inner tube facing said enclosed jacketed area is threaded orknurled to increase the surface area and thereby improve heat transfer.